1m9q Citations

Conformational changes in nitric oxide synthases induced by chlorzoxazone and nitroindazoles: crystallographic and computational analyses of inhibitor potency.

Rosenfeld RJ, Garcin ED, Panda K, Andersson G, Aberg A, Wallace AV, Morris GM, Olson AJ, Stuehr DJ, Tainer JA, Getzoff ED
Biochemistry 41 13915-25 (2002)
Related entries: 1m8d, 1m8e, 1m8h, 1m8i, 1m9j, 1m9k, 1m9m, 1m9r, 1m9t

Cited: 34 times
EuropePMC logo PMID: 12437348

Abstract

Nitric oxide is a key signaling molecule in many biological processes, making regulation of nitric oxide levels highly desirable for human medicine and for advancing our understanding of basic physiology. Designing inhibitors to specifically target one of the three nitric oxide synthase (NOS) isozymes that form nitric oxide from the L-Arg substrate poses a significant challenge due to the overwhelmingly conserved active sites. We report here 10 new X-ray crystallographic structures of inducible and endothelial NOS oxygenase domains cocrystallized with chlorzoxazone and four nitroindazoles: 5-nitroindazole, 6-nitroindazole, 7-nitroindazole, and 3-bromo-7-nitroindazole. Each of these bicyclic aromatic inhibitors has only one hydrogen bond donor and therefore cannot form the bidentate hydrogen bonds that the L-Arg substrate makes with Glu371. Instead, all of these inhibitors induce a conformational change in Glu371, creating an active site with altered molecular recognition properties. The cost of this conformational change is approximately 1-2 kcal, based on our measured constants for inhibitor binding to the wild-type and E371A mutant proteins. These inhibitors derive affinity by pi-stacking above the heme and replacing both intramolecular (Glu371-Met368) and intermolecular (substrate-Trp366) hydrogen bonds to the beta-sheet architecture underlying the active site. When bound to NOS, high-affinity inhibitors in this class are planar, whereas weaker inhibitors are nonplanar. Isozyme differences were observed in the pterin cofactor site, the heme propionate, and inhibitor positions. Computational docking predictions match the crystallographic results, including the Glu371 conformational change and inhibitor-binding orientations, and support a combined crystallographic and computational approach to isozyme-specific NOS inhibitor analysis and design.

Articles - 1m9q mentioned but not cited (2)

  1. Association of endothelial nitric oxide synthase gene variants with preeclampsia. Shaheen G, Jahan S, Bibi N, Ullah A, Faryal R, Almajwal A, Afsar T, Al-Disi D, Abulmeaty M, Al Khuraif AA, Arshad M, Razak S. Reprod Health 18 163 (2021)
  2. Network Pharmacology and Molecular Docking-Based Prediction of the Mechanism of Qianghuo Shengshi Decoction against Rheumatoid Arthritis. Zeng Z, Hu J, Jiang J, Xiao G, Yang R, Li S, Li Y, Huang H, Zhong H, Bi X. Biomed Res Int 2021 6623912 (2021)


Reviews citing this publication (4)

  1. Developing master keys to brain pathology, cancer and aging from the structural biology of proteins controlling reactive oxygen species and DNA repair. Perry JJ, Fan L, Tainer JA. Neuroscience 145 1280-1299 (2007)
  2. Nitric oxide synthase and structure-based inhibitor design. Poulos TL, Li H. Nitric Oxide 63 68-77 (2017)
  3. Use of Computational Biochemistry for Elucidating Molecular Mechanisms of Nitric Oxide Synthase. Bignon E, Rizza S, Filomeni G, Papaleo E. Comput Struct Biotechnol J 17 415-429 (2019)
  4. Biology and chemistry of the inhibition of nitric oxide synthases by pteridine-derivatives as therapeutic agents. Matter H, Kotsonis P. Med Res Rev 24 662-684 (2004)

Articles citing this publication (28)

  1. Structural basis for isozyme-specific regulation of electron transfer in nitric-oxide synthase. Garcin ED, Bruns CM, Lloyd SJ, Hosfield DJ, Tiso M, Gachhui R, Stuehr DJ, Tainer JA, Getzoff ED. J Biol Chem 279 37918-37927 (2004)
  2. Anchored plasticity opens doors for selective inhibitor design in nitric oxide synthase. Garcin ED, Arvai AS, Rosenfeld RJ, Kroeger MD, Crane BR, Andersson G, Andrews G, Hamley PJ, Mallinder PR, Nicholls DJ, St-Gallay SA, Tinker AC, Gensmantel NP, Mete A, Cheshire DR, Connolly S, Stuehr DJ, Aberg A, Wallace AV, Tainer JA, Getzoff ED. Nat Chem Biol 4 700-707 (2008)
  3. Structure-based reassessment of the caveolin signaling model: do caveolae regulate signaling through caveolin-protein interactions? Collins BM, Davis MJ, Hancock JF, Parton RG. Dev Cell 23 11-20 (2012)
  4. Statistical analysis of interface similarity in crystals of homologous proteins. Xu Q, Canutescu AA, Wang G, Shapovalov M, Obradovic Z, Dunbrack RL. J Mol Biol 381 487-507 (2008)
  5. Automated docking of ligands to an artificial active site: augmenting crystallographic analysis with computer modeling. Rosenfeld RJ, Goodsell DS, Musah RA, Morris GM, Goodin DB, Olson AJ. J Comput Aided Mol Des 17 525-536 (2003)
  6. Prediction of binding modes for ligands in the cytochromes P450 and other heme-containing proteins. Kirton SB, Murray CW, Verdonk ML, Taylor RD. Proteins 58 836-844 (2005)
  7. Deciphering the binding of caveolin-1 to client protein endothelial nitric-oxide synthase (eNOS): scaffolding subdomain identification, interaction modeling, and biological significance. Trane AE, Pavlov D, Sharma A, Saqib U, Lau K, van Petegem F, Minshall RD, Roman LJ, Bernatchez PN. J Biol Chem 289 13273-13283 (2014)
  8. The origin of enantioselectivity in aldolase antibodies: crystal structure, site-directed mutagenesis, and computational analysis. Zhu X, Tanaka F, Hu Y, Heine A, Fuller R, Zhong G, Olson AJ, Lerner RA, Barbas CF, Wilson IA. J Mol Biol 343 1269-1280 (2004)
  9. Nitric-oxide synthase forms N-NO-pterin and S-NO-cys: implications for activity, allostery, and regulation. Rosenfeld RJ, Bonaventura J, Szymczyna BR, MacCoss MJ, Arvai AS, Yates JR, Tainer JA, Getzoff ED. J Biol Chem 285 31581-31589 (2010)
  10. Angiogenesis related genes NOS3, CD14, MMP3 and IL4R are associated to VEGF gene expression and circulating levels in healthy adults. Saleh A, Stathopoulou MG, Dadé S, Ndiaye NC, Azimi-Nezhad M, Murray H, Masson C, Lamont J, Fitzgerald P, Visvikis-Siest S. BMC Med Genet 16 90 (2015)
  11. Conformational analysis of N,N-disubstituted-1,4-diazepane orexin receptor antagonists and implications for receptor binding. Cox CD, McGaughey GB, Bogusky MJ, Whitman DB, Ball RG, Winrow CJ, Renger JJ, Coleman PJ. Bioorg Med Chem Lett 19 2997-3001 (2009)
  12. Dual binding mode of "bitter sugars" to their human bitter taste receptor target. Fierro F, Giorgetti A, Carloni P, Meyerhof W, Alfonso-Prieto M. Sci Rep 9 8437 (2019)
  13. Food-related compounds that modulate expression of inducible nitric oxide synthase may act as its inhibitors. Maldonado-Rojas W, Olivero-Verbel J. Molecules 17 8118-8135 (2012)
  14. Inhibitory effects of a series of 7-substituted-indazoles toward nitric oxide synthases: particular potency of 1H-indazole-7-carbonitrile. Cottyn B, Acher F, Ramassamy B, Alvey L, Lepoivre M, Frapart Y, Stuehr D, Mansuy D, Boucher JL, Vichard D. Bioorg Med Chem 16 5962-5973 (2008)
  15. Potential Valorization of Edible Nuts By-Products: Exploring the Immune-Modulatory and Antioxidants Effects of Selected Nut Shells Extracts in Relation to Their Metabolic Profiles. Salem MA, Aborehab NM, Al-Karmalawy AA, Fernie AR, Alseekh S, Ezzat SM. Antioxidants (Basel) 11 462 (2022)
  16. Theoretical studies on the binding of rhenium(I) complexes to inducible nitric oxide synthase. Oliveira BL, Moreira IS, Fernandes PA, Ramos MJ, Santos I, Correia JD. J Mol Graph Model 45 13-25 (2013)
  17. Synthesis and biological evaluation of indazole derivatives. Claramunt RM, López C, López A, Pérez-Medina C, Pérez-Torralba M, Alkorta I, Elguero J, Escames G, Acuña-Castroviejo D. Eur J Med Chem 46 1439-1447 (2011)
  18. Synthesis of nitric oxide in human osteoblasts in response to physiologic stimulation of electrotherapy. Hamed A, Kim P, Cho M. Ann Biomed Eng 34 1908-1916 (2006)
  19. Theoretical calculations of a model of NOS indazole inhibitors: interaction of aromatic compounds with Zn-porphyrins. Elguero J, Alkorta I, Claramunt RM, López C, Sanz D, María DS. Bioorg Med Chem 17 8027-8031 (2009)
  20. Nitric Oxide Synthase Inhibitors into the Clinic at Last. Dao VT, Elbatreek MH, Fuchß T, Grädler U, Schmidt HHHW, Shah AM, Wallace A, Knowles R. Handb Exp Pharmacol 264 169-204 (2021)
  21. Discovery of a series of aminopiperidines as novel iNOS inhibitors. Le Bourdonnec B, Leister LK, Ajello CA, Cassel JA, Seida PR, O'Hare H, Gu M, Chu GH, Tuthill PA, DeHaven RN, Dolle RE. Bioorg Med Chem Lett 18 336-343 (2008)
  22. Insights into the structural determinants for selective inhibition of nitric oxide synthase isoforms. Oliveira BL, Moreira IS, Fernandes PA, Ramos MJ, Santos I, Correia JD. J Mol Model 19 1537-1551 (2013)
  23. Antioxidant, Anti-α-Glucosidase, Antityrosinase, and Anti-Inflammatory Activities of Bioactive Components from Morus alba. Hsu JH, Yang CS, Chen JJ. Antioxidants (Basel) 11 2222 (2022)
  24. Structural and Mechanistic Studies of the Rare Myristoylation Signal of the Feline Immunodeficiency Virus. Brown JB, Summers HR, Brown LA, Marchant J, Canova PN, O'Hern CT, Abbott ST, Nyaunu C, Maxwell S, Johnson T, Moser MB, Ablan SD, Carter H, Freed EO, Summers MF. J Mol Biol 432 4076-4091 (2020)
  25. Pellucidin A promotes antinociceptive activity by peripheral mechanisms inhibiting COX-2 and NOS: In vivo and in silico study. Queiroz APS, Freitas MCC, Silva JRA, Lima AB, Sawada L, Martins Monteiro RF, de Freitas ACGA, Maués LAL, Arruda AC, Silva MN, Maia CSF, Fontes-Júnior EA, do Nascimento JLM, Arruda MSP, Bastos GNT. PLoS One 15 e0238834 (2020)
  26. Bioactive fraction from Plumeria obtusa L. attenuates LPS-induced acute lung injury in mice and inflammation in RAW 264.7 macrophages: LC/QToF-MS and molecular docking. Eloutify YT, El-Shiekh RA, Ibrahim KM, Hamed AR, Al-Karmalawy AA, Shokry AA, Ahmed YH, Avula B, Katragunta K, Khan IA, Meselhy MR, Meselhy MR. Inflammopharmacology 31 859-875 (2023)
  27. Insights into human eNOS, nNOS and iNOS structures and medicinal indications from statistical analyses of their interactions with bound compounds. Dong J, Li D, Kang L, Luo C, Wang J. Biophys Rep 9 159-175 (2023)
  28. Investigations on the role of π-π interactions and π-π networks in eNOS and nNOS proteins. Vaideeswaran S, Ramaiah S. Bioorg Chem 49 16-23 (2013)


Related citations provided by authors (1)

  1. Structure of nitric oxide synthase oxygenase dimer with pterin and substrate. Crane BR, Arvai AS, Ghosh DK, Wu C, Getzoff ED, Stuehr DJ, Tainer JA Science 279 2121-2126 (1998)

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